Photon Sieves Advance Toward a Solar Observatory Concept

Image Credit: Kevin Denis

To better understand the Sun’s behavior, scientists want to observe very small processes close to the surface that emit light in extreme ultraviolet wavelengths – 10 times shorter than the wavelengths of visible light.

Imaging in extreme ultraviolet, or EUV light, hasn’t been done at the level of detail needed to distinguish these processes, which have been inferred through advanced computer models. This is because conventional lenses block EUV light, and EUV mirrors cannot be polished accurately enough for them to achieve the ultimate resolution of tiny features.

To explore this blind spot, Goddard researchers say thin-film photon sieves, which diffract EUV light to a focal point, could provide 10- to 20-times greater resolution than the images of the Sun captured by the Solar Dynamics Observatory. Viewing these processes in motion could answer significant questions about the nature of our star, how the Sun’s upper atmosphere is heated, the origins of flares and coronal mass ejections, and the space weather these solar eruptions create throughout the solar system.

“It’s about unlocking the clues to what causes the Sun’s corona to be energized,” Goddard physicist Adrian Daw said, “and of course that’s what drives space weather.”

Daw is working with a Goddard team including scientists Anne-Marie Novo-Gradac and Doug Rabin and engineers Kevin Denis and Meng Ping Chang. Someday, they hope to achieve milliarcsecond resolution in the EUV spectrum to observe these processes. This would be like being able to see a city the size of Los Angeles on the surface of the Sun.

Pioneering work in thin-film photon sieves like the one above, produced by Goddard’s Kevin Denis, promise to someday deliver high-resolution, extreme ultraviolet images of the solar corona. “SDO’s cameras are able to image small solar flares down to the arcsecond level,” Daw said. “A photon sieve could achieve 0.05-arcsecond resolution, or 50 milliarcseconds, in its current version.”

While still perfecting larger and finer sieves for a future solar observatory mission concept, the team has used their progress to calibrate the sensors of several sounding rocket missions. These include the Extreme Ultraviolet Normal Incidence Spectrograph (EUNIS) mission, which measured ionized elements in the Sun’s atmosphere by separating the EUV light wavelengths emitted by different atoms and ions at extremely high temperatures.

The sieve team is also serving as co-investigators on the Multi-slit Solar Explorer (MUSE) mission, selected as a NASA Heliophysics MIDEX this February. There they will again use sieves to calibrate the mission’s EUV sensor, a multi-slit spectrometer which is an advancement of EUNIS’s instrument. MUSE seeks to obtain the highest-resolution measurements ever captured of the solar corona and transition region, where the Sun’s lower atmosphere interacts with the much hotter corona above.

To fully realize the value of the sieves in space, however, the team needs a formation-flying telescope system to make use of the long focal length they provide. Their opportunity came in the form of a National Science Foundation project managed by the University of Illinois at Urbana-Champaign. The Virtual Super-Resolution Optics with Reconfigurable Swarms (VISORS) experiment will employ two CubeSats using a Goddard sieve as a diffracting lens. The lead spacecraft will hold the sieve while its solar panels serve as a sunshade for the sensor spacecraft that will collect the focused EUV light.

Photon sieves are usually created by precisely etching millions of holes through an EUV-blocking membrane. The light waves that diffract through the holes interact to create a focus at a distance from the sieve. The holes start at 143 microns in diameter (just over 0.1 mm) near the center and narrow down to 2 microns in diameter in the outer rings of the film.

To observe the Sun, Denis has been pioneering larger and larger sieves on thinner films. His team is currently perfecting 170-mm diameter sieves that could power a telescope like VISORS. The films are just 25 microns thick. In parallel the team is perfecting techniques to significantly increase efficiency by reducing the membrane thickness to under a micron so that it will transmit EUV light. The membrane thickness and material are chosen to help focus the light.

Traditional sieves create a sharp image but aren’t very efficient—too much of the light is lost along the way. To address this shortcoming, Denis has fabricated ultra-thin structured polymer films that can direct much more of the light to the focus. The thin films support a variant of the Fresnel zone plate, an older type of lens originally patterned on glass which focuses light using a series of concentric rings of alternating transparent and opaque surfaces. Fresnel zone plates use diffraction, unlike standard telescopes which refract light through a lens or reflect off a mirror (See CuttingEdge Summer 2016, Page 18).

Denis and the team earned a patent for fabricating the ultra-thin structured polymer films.

“VISORS will be the pathfinder for a bigger mission that we will propose in the not-too-distant future,” Daw said. “We envision a multi-channel telescope, where you actually do have different sieves and detector systems to study different aspects of the Sun’s inner atmosphere.”

Similar to SDO’s Atmospheric Imaging Assembly (AIA), which uses four telescopes to capture eight bandwidths of light, their system would incorporate up to six sieves in the lead spacecraft and six detectors on the rear spacecraft. This will allow scientists to dissect different processes within the Sun’s atmosphere with sieves tailored to focus in on the EUV light wavelengths produced by different elements at different temperatures.

Distributed systems like a formation-flying observatory bring their own challenges. That is why the team is working closely with Novo-Gradac and Rabin, who are developing the precision flying and sunshade technologies to round out the observatory concept (see CuttingEdge Winter 2021, Page 11; and Summer 2020, Page 2).

Adrian.Daw@NASA.gov or 301.286.2278

Kevin.L.Denis@NASA.gov or 301.286.7935